We demonstrate by numerical analysis that quantitatively useful barrier magnitudes may be obtained within the framework of the molecular orbital method. Use is made of a theorem by K. F. Freed that the first derivative at a midpoint between adjacent extrema in a sinusoidal potential energy curve can be determined to second order for Hartreehyphen;Fock wavefunctions and the fact that potential energy functions of the formElpar;xrpar; equals; ax2plus; bx4plus; cthinsp;explpar;minus;gx2rpar;,Elpar;xrpar; equals; ax2plus; bx4plus; fx3,Elpar;xrpar; equals; lpar;1sol;2 rpar;jthinsp;Vjlpar;1minus;cosjxrpar;,are known to represent all existing rotation and inversion barriers within experimental error. We then show by illustrative computations that the stated potential functions usually have first derivatives (at midpoints between adjacent extrema) equal, withinplusmn; 5 percnt;, to first derivatives of the sine curve arcs required by Freed's theorem. Thus, barriers may be predicted adequately byab initioand, in principle, by semiempirical molecular orbital methods. This suggests that quantitative prediction of conformations of large organic molecules may be possible.
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